壳聚糖锌离子固定化亲和层析填料的制备与性质

目的:制备了壳聚糖Zn2+固定化亲和层析填料,并对其性能进行了研究。方法:采用反相悬浮法制备了交联壳聚糖;再以环氧氯丙烷为活化剂,乙二胺为螯合配基,制备了固定化亲和层析填料;表征了其有效粒径以及均匀系数、含水量、失重率、氨基含量、骨架密度、堆积密度以及孔度值。从时间、加入ZnCl2的浓度、温度、pH方面对Zn2+固定化条件进行了优选,并确定了Zn2+的固定化量。含组氨酸标签的乙醛脱氢酶粗酶液,经硫酸铵盐析后,考察了壳聚糖Zn2+固定化亲和层析填料的亲和性能。结果:制备的填料有效粒径为105μm;均匀系数为1.46;含水量为58.03%;失重率为85.43%;氨基含量为9.20mmol/g;骨架密度为1.217 8g/ml;堆积密度为0.843 2g/ml;孔度值为36.40%。固定化Zn2+的最佳条件是:时间3 h、加入ZnCl2溶液浓度0.1mol/L、温度28℃、pH 5.5;且此条件下,亲和层析填料中Zn2+固定化量为3.35mmol/g。壳聚糖Zn2+固定化亲和层析填料对乙醛脱氢酶的亲和性能为4.14IU/g(干重)。结论:制备了壳聚糖Zn2+固定化亲和层析填料,可用于带有组氨酸标签重组蛋白的快速分离与纯化。     

Purification of alcohol dehydrogenase from Drosophila by general-ligand affinity chromatography.

A method for the purification of alcohol dehydrogenase from Drosophila melanogaster is described. The method makes use of 8-(6-aminohexyl)amino-5'-AMP, immobilized on Sepharose 4B, as an affinity ligand. Since alcohol dehydrogenase from Drosophila shows weak affinity for this column, a novel technique was developed to separate alcohol dehydrogenase from both unbound proteins and more strongly bound enzymes. The purification procedure is simple to operate and give a homogeneous preparation in good yield after only three steps.     

Affinity chromatography of urokinase on an agarose derivative coupled with pyroglutamyl-lysyl-leucyl-argininal

Pyroglutamyl-lysyl-leucyl-argininal (Pyr-Lys-Leu-Argal) immobilized on gel matrix through the epsilon-amino group of its lysine residue was shown to be an efficient biospecific affinity adsorbent for purification of urokinase. Pyr-Lys-Leu-Argal dibutylacetal, a precursor of this immobilized ligand, was synthesized by a fragment condensation procedure, in which one of the thermolysin-digestion products of leupeptin dibutylacetal, H-Leu-Argal dibutylacetal, was used as a key intermediate. The precursor was coupled to CH-Sepharose 4B with the aid of a water-soluble carbodiimide, and its acetal protecting group was then removed by mild acid treatment to free the essential aldehyde function. The Sepharose derivative thus prepared was shown to adsorb urokinase selectively and effectively from a crude human urine preparation at neutral pH and to release the bound enzyme under mild acidic conditions. The present technique afforded a highly purified urokinase preparation abundant in the high-molecular form with 90% recovery. The complex formed between urokinase and the immobilized ligand was found to have a dissociation constant of about 2 X 10(-4)M.     

Fundamental differences in bioaffinity of amino acid dehydrogenases for N6- and S6-linked immobilized cofactors using kinetic-based enzyme-capture strategies

Five different immobilized NAD+ derivatives were employed to compare the behavior of four amino acid dehydrogenases chromatographed using kinetic-based enzyme capture strategies (KBECS): S6-, N6-, N1-, 8'-azo-, and pyrophosphate-linked immobilized NAD+. The amino acid dehydrogenases were NAD+-dependent phenylalanine (EC 1.4.1.20), alanine (EC 1.4.1.1), and leucine (EC 1.4.1.9) dehydrogenases from various microbial species and NAD(P)+-dependent glutamate dehydrogenase from bovine liver (GDH; EC 1.4.1.3). KBECS for bovine heart L-lactate dehydrogenase (EC 1.1.1.27) and yeast alcohol dehydrogenase (EC 1.1.1.1) were also applied to assist in a preliminary assessment of the immobilized cofactor derivatives. Results confirm that the majority of the enzymes studied retained affinity for NAD+ immobilized through an N6 linkage, as opposed to an N1 linkage, replacement of the nitrogen with sulfur to produce an S6 linkage, or attachment of the cofactor through the C8 position or the pyrophosphate group of the cofactor. The one exception to this was the dual-cofactor-specific GDH from bovine liver, which showed no affinity for N6-linked NAD+ but was biospecifically adsorbed to S6-linked NAD+ derivatives in the presence of its soluble KBEC ligand. The molecular basis for this is discussed together with the implications for future development and application of KBECS.     

Studies on the use of sepharose-N-(6-aminohexanoyl)-2-amino-2-deoxy-D-glucopyranose for the large-scale purification of hepatic glucokinase.

The synthesis of N-(6-aminohexanoyl)-2-amino-2-deoxy-D-glucose is described and it was shown to be a competitive inhibitor (Ki, 0.75 mM) with respect to glucose of rat hepatic glucokinase (EC 2.7.1.2). After attachment to CNBr-activated Sepharose 4B, this derivative was able to remove glucokinase quantitatively from crude liver extracts and release it when the columns were developed with glucose, glucosamine, N-acetyl-glucosamine or KC1. Repeated exposure of the columns to liver extracts led to rapid loss in their effectiveness as affinity matrices because proteins other than glucokinase are bound to the columns. The nature of such protein binding and methods for the rejuvenation of "used" columns are discussed along with the effect of the mode of preparation of the Sepharose-ligand conjugate and the concentration of bound ligand on the purification of glucokinase. Glucose 6-phosphate dehydrogenase is cited as an example of both non-specific protein binding to the affinity column and of the importance of the control of ligand concentration in removing such non-specifically bound proteins. Some guidelines emerged that should be generally applicable to other systems, particularly those which involve affinity chromatography of enzymes that are present in tissue extracts in very low amounts and possess only a relatively low association constant for the immobilized ligand.     

A "stripping" ligand tactic for use with the kinetic locking-on strategy: its use in the resolution and bioaffinity chromatographic purification of NAD(+)-dependent dehydrogenases.

The kinetic locking-on strategy utilizes soluble analogues of the target enzymes' specific substrate to promote selective adsorption of individual NAD(+)-dependent dehydrogenases on their complementary immobilized cofactor derivative. Application of this strategy to the purification of NAD(+)-dependent dehydrogenases from crude extracts has proven that it can yield bioaffinity systems capable of producing one-chromatographic-step purifications with yields approaching 100%. However, in some cases the purified enzyme preparation was found to be contaminated with other proteins weakly bound to the immobilized cofactor derivative through binary complex formation and/or nonspecific interactions, which continuously "dribbled" off the matrix during the chromatographic procedure. The fact that this problem can be overcome by including a short pulse of 5'-AMP (stripping ligand) in the irrigant a couple of column volumes prior to the discontinuation of the specific substrate analogue (locking-on ligand) is clear from the results presented in this report. The general effectiveness of this auxiliary tactic has been assessed using model studies and through incorporation into an actual purification from a crude cellular extract. The results confirm the usefulness of the stripping-ligand tactic for the resolution and purification of NAD(+)-dependent dehydrogenases when using the locking-on strategy. These studies have been carried out using bovine liver glutamate dehydrogenase (GDH, EC 1.4.1.3), yeast alcohol dehydrogenase (YADH, EC 1.1.1.1), porcine heart mitochondrial malate dehydrogenase (mMDH, EC 1.1.1.37), and bovine heart L-lactate dehydrogenase (l-LDH, EC 1.1.1.27).     

Immobilized-enzyme continuous-flow reactor incorporating continuous electrochemical regeneration of NAD

Electrochemical regeneration of the cofactor nicotinamide adenine dinucleotide (NAD) from its reduced form (NADH) has been coupled with the alcoholdehydrogenation reaction which consumes NAD and produces NADU using alcohol dehydrogenase bound to alumina. Alcohol (reactant) is added directly to the system while aldehyde (product) leaves the system through an ultrafiltration membrane which prevents loss of the cofactor. This system provides a continuous-flow process for carrying out a cofactor-requiring enzymatic reaction with no net loss or consumption of enzyme or cofactor and without the use of reagents for regenerating the cofactor. Although the process shown here is not economically practical, it may be a harbinger of useful and technically feasible chemical reaction systems based on immobilized enzymes requiring cofactors.     

A “Stripping” Ligand Tactic for Use with the Kinetic Locking-on Strategy: Its Use in the Resolution and Bioaffinity Chromatographic Purification of NAD-Dependent Dehydrogenases

The kinetic locking-on strategy utilizes soluble analogues of the target enzymes' specific substrate to promote selective adsorption of individual NAD⁺-dependent dehydrogenases on their complementary immobilized cofactor derivative. Application of this strategy to the purification of NAD⁺-dependent dehydrogenases from crude extracts has proven that it can yield bioaffinity systems capable of producing one-chromatographic-step purifications with yields approaching 100%. However, in some cases the purified enzyme preparation was found to be contaminated with other proteins weakly bound to the immobilized cofactor derivative through binary complex formation and/or nonspecific interactions, which continuously “dribbled” off the matrix during the chromatographic procedure. The fact that this problem can be overcome by including a short pulse of 5′-AMP (stripping ligand) in the irrigant a couple of column volumes prior to the discontinuation of the specific substrate analogue (locking-on ligand) is clear from the results presented in this report. The general effectiveness of this auxiliary tactic has been assessed using model studies and through incorporation into an actual purification from a crude cellular extract. The results confirm the usefulness of the stripping-ligand tactic for the resolution and purification of NAD⁺-dependent dehydrogenases when using the locking-on strategy. These studies have been carried out using bovine liver glutamate dehydrogenase (GDH, EC 1.4.1.3), yeast alcohol dehydrogenase (YADH, EC 1.1.1.1), porcine heart mitochondrial malate dehydrogenase (mMDH, EC 1.1.1.37), and bovine heart -lactate dehydrogenase ( -LDH, EC 1.1.1.27).     

Double-ternary complex affinity chromatography: preparation of alcohol dehydrogenases.

A general affinity chromatographic method for alcohol dehydrogenase purification has been developed by employing immobilized 4-substituted pyrazole derivatives that isolate the enzyme through formation of a specific ternary complex. Sepharose 4B is activated with 300 mg of cyanogen bromide/ml of packed gel and coupled to 4-[3-(N-6-aminocaproyl)aminopropyl]pyrazole. From crude liver extracts in 50 mM phosphate-0.37 mM nicotinamide adenine dinucleotide, pH 7.5, alcohol dehydrogenase is optimally bound at a capacity of 4-5 mg of enzyme/ml of gel. Addition of ethanol, propanol, or butanol, 500 mM, results in the formation of a second ternary complex, which allows the elution of bound enzyme in high yield and purity. This double-ternary complex affinity chromatography has been applied successfully to human, horse, rat, and rabbit liver extracts to isolate the respective homogeneous alcohol dehydrogenases.     

A kinetic locking-on strategy for bioaffinity purification: further studies with alcohol dehydrogenase

The kinetic locking-on strategy improves the selectivity of protein purification procedures based on immobilized cofactor derivatives through use of enzyme-specific substrate analogues in irrigants to promote biospecific adsorption. This paper describes the development and application of this strategy to the one-chromatographic step affinity purification of NAD(P)+-dependent alcohol dehydrogenases using 8'-azo-linked immobilized NAD(P)+, S6-linked and N6-linked immobilized NAD+, and N6-linked immobilized NADP+ derivatives. These studies were carried out using alcohol dehydrogenases from Saccharomyces cerevisiae (YADH, EC 1.1.1.1), equine liver (HLADH, EC 1.1.1.1), and Thermoanaerobium brockii (TBADH, EC 1.1.1.2). The results reveal that the factors which require careful consideration before development of a truly biospecific system based on the locking-on strategy include: (i) the stability of the immobilized cofactor derivative; (ii) the spacer-arm composition of the affinity derivative; (iii) the accessible immobilized cofactor concentration; (iv) the soluble locking-on ligand concentration; (v) the dissociation constant of locking-on ligand, and (vi) the identification and elimination of nonbiospecific interference. The S6-linked immobilized NAD+ derivative (synthesized with a hydrophilic spacer arm) proved to be the most suitable of the affinity adsorbents investigated in the present study for use with the locking-on strategy. This conclusion was based primarily on the observations that this affinity adsorbent was stable, retained cofactor activity with the "test" enzymes under study, and was not prone to nonbiospecific interactions. Using this immobilized derivative in conjunction with the locking-on strategy, alcohol dehydrogenase from Saccharomyces cerevisiae was purified to electrophoretic homogeneity in a single affinity chromatographic step.     

Affinity chromatography of sn-glycerol-3-phosphate dehydrogenase on immobilized NAD

Three types of potential affinity chromatography columns have been examined for the purification of sn-glycerol-4-phosphate dehydrogenase (EC 1.1.1.8) from rabbit tissues. Each column contained nicotinamide adenine dinucleotide (NAD) covalently attached to an agarose matrix with a different mode of attachment for each column. The most effective column was one in which the NAD was linked to the agarose via the C-8 position of the adenine moiety. Release of the bound enzyme from this column was accomplished by elution with NADH or NAD. The enzymes from brain, heart, kidney, muscle and liver were purified using this procedure with nearly quantitative yields and up to a 90-fold purification. The binding capacity and elution profiles were dependent upon pH, ionic strength and temperature. The capacity was lowest at pH 7 and increased at higher and lower values. Increasing ionic strength and higher temperatures decreased the binding capacities.     

A novel approach for affinity-based screening of target specific ligands: application of photoreactive D-glyceraldehyde-3-phosphate dehydrogenase

A novel application of the photoaffinity technique has been developed for the efficient discovery of small ligand and macromolecule interaction. The approach, photoaffinity capture, uses a photoreactive protein together with immobilized ligand for the rapid screening of competitive inhibitors. The set of photoreactive glyceraldehyde-3-phosphate dehydrogenase (photo-GAPDH) and immobilized dye ligand was prepared and examined as a model system. The photo-GAPDH was shown to efficiently capture the immobilized ligand. When nonimmobilized competitive ligands were included in the system, the capture was prevented in accordance with the affinity of the ligands. The present approach would provide an efficient tool for affinity-based screening of ligand libraries.     

Beta-glycosylamidine as a ligand for affinity chromatography tailored to the glycon substrate specificity of beta-glycosidases

An affinity adsorbent for beta-glycosidases has been prepared by using beta-glycosylamidine as a ligand. beta-Glucosylamidine and beta-galactosylamidine, highly potent and selective inhibitors of beta-glucosidases and beta-galactosidases, respectively, were immobilized by a novel one-pot procedure involving the addition of a beta-glycosylamine and 2-iminothiolane.HCl simultaneously to a matrix modified with maleimido groups via an appropriate spacer to give an affinity adsorbent for beta-glucosidases and beta-galactosidases, respectively. This one-pot procedure enables various beta-glycosylamidine ligands to be formed and immobilized conveniently according to the glycon substrate specificities of the enzymes. A crude enzyme extract from tea leaves (Camellia sinensis) and a beta-galactosidase from Penicillium multicolor were chromatographed directly on each affinity adsorbent to give a beta-glucosidase and a beta-galactosidase to apparent homogeneity in one step by eluting the column with glucose or by a gradient NaCl elution, respectively. The beta-glucosidase and beta-galactosidase were inhibited competitively by a soluble form of the corresponding beta-glycosylamidine ligand with an inhibition constant (K(i)) of 2.1 and 0.80 microM, respectively. Neither enzyme was bound to the adsorbent with a mismatched ligand, indicating that the binding of the glycosidases was of specific nature that corresponds to the glycon substrate specificity of the enzymes. The ease of preparation and the selective nature of the affinity adsorbent should promise a large-scale preparation of the affinity adsorbent for the purification and removal of specific glycosidases according to their glycon substrate specificities.     

Active site of human liver aldehyde dehydrogenase

Bromoacetophenone (2-bromo-1-phenylethanone) functions as an affinity reagent for human aldehyde dehydrogenase (EC 1.2.1.3) and has been found specifically to label a unique tryptic peptide in the enzyme. Amino-terminal sequence analysis of the labeled peptide after purification by two different procedures revealed the following sequence: Val-Thr-Leu-Glu-Leu-Gly-Gly-Lys. Radioactivity was found to be associated with the glutamate residue, which was identified as Glu-268 by reference to the known amino acid sequence. This paper constitutes the first identification of an active site of aldehyde dehydrogenase.     

Affinity Chromatography of Sn-Glycerol-3-Phosphate Dehydrogenase on Immobilized NAD

Three types of potential affinity chromatography columns have been examined for the purification of sn-glycerol-3-phosphate dehydrogenase (EC 1.1.l.R) from rabbit tissues. Each column contained nicotinamide adenine dinucleotide (NAD) covalently attached to an agarose matrix with a different mode of attachment for each column. The most effective column was one in which the NAD was linked to the agarose via the C-8 position of the adenine moiety. Please of the bound enzyme from this column was accomplished by elution with NADH or MAD. The enzymes from brain, heart, kidney, muscle and liver were purified using this procedure with nearly quantitative yields and up to a 90-fold purification. The binding capacity and elution profiles were dependent upon pH, ionic strength and temperature. The capacity was lowest at pH 7 and increased at higher and lower values. Increasing ionic strength and higher temperatures decreased the binding capacities.     

Structure-function relationship in glycosylated alpha-chymotrypsin as probed by IMAC and IMACE.

Chemical glycosylation of bovine alpha-chymotrypsin, by a glucosamine adduct on the carboxyl group, results in the modification of its catalytic activity. The structural alterations of alpha-chymotrypsin resulting from its glycosylation are studied by immobilized metal-ion affinity chromatography (IMAC) and immobilized metal-ion affinity capillary electrophoresis (IMACE). The chemical glycosylation of alpha-chymotrypsin generates two distinct subpopulations of the protein: one which totally loses the initial affinity for IDA-Cu(II) and another which exhibits an increased affinity for the metal chelate ligand.     

Immobilization of enzymes on PTFE surfaces.

Membranes and powders prepared from PTFE (polytetrafluorethylene) were investigated for their potential use as multifunctional supports for enzymes. The obtained bioactive materials are valuable for the construction of biosensors and enzyme reactors. To allow covalent coupling of enzymes to PTFE, the surface of the material was treated with elementary sodium followed by oxidation with ozone or hydrogen peroxide.%Derivatization steps were optimized in order to achieve highest enzyme loading and short reaction times. Alliinase (EC 4.4.1.4) and L-lactic dehydrogenase (EC 1.1.1.27) were chosen as model enzymes and were either immobilized by covalent coupling or fixed indirectly by a sugar-lectin binding. For the latter method, the sugar mannan was bound to the membrane surface as an anchor for layers of the lectin concanavalin A and the alliinase. Highest alliinase loading was achieved at 0.2 microg x cm(-2). Immobilization of alliinase via the lectin concanavalin A and a bifunctional epoxide gave the best long-term stability.%L-Lactic dehydrogenase was most sufficiently immobilized by using benzoquinone as spacer. These procedures show several advantages: 1) enzymes can be immobilized under physiological conditions, 2) an enzyme-multilayer can be achieved, and 3) protein layers are renewable.     

Purification of liver aldehyde dehydrogenase by p-hydroxyacetophenone-sepharose affinity matrix and the coelution of chloramphenicol acetyl transferase from the same matrix with recombinantly expressed aldehyde dehydrogenase.

p-Hydroxyacetophenone was coupled to epoxy-activated Sepharose 6B to generate an affinity chromatographic matrix to purify aldehyde dehydrogenase. Purified beef liver mitochondrial aldehyde dehydrogenase specifically bound to the support and could be eluted with p-hydroxyacetophenone. A post-ammonium sulfate (30-55%) fraction of bovine liver was applied to the affinity gel column and aldehyde dehydrogenase was effectively purified, although not to complete homogeneity, indicating the potential selectivity of the matrix. Both beef liver cytosolic and mitochondrial aldehyde dehydrogenase bound to the column. A post-Cibacron blue Sepharose Cl-6B affinity-fractionated liver mitochondrial aldehyde dehydrogenase was purified to complete homogeneity by p-hydroxyacetophenone-Sepharose, thus eliminating the need for the isoelectric focusing step often employed. p-Hydroxyacetophenone was found to be a competitive inhibitor against propionaldehyde and noncompetitive against NAD. Escherichia coli lysates of recombinantly expressed aldehyde dehydrogenase were purified from E. coli lysates with one major 25-kDa protein contaminant also binding to the column, as detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. The 25-kDa contaminant was found to be chloramphenicol acetyl transferase from sequence analysis and binding studies.     

Chemical modification of aldehyde dehydrogenase by a vinyl ketone analogue of an insect pheromone.

A major component of the sex pheromone from the tobacco budworm moth Heliothis virescens is a C16 straight-chain aldehyde with a single unsaturation at the eleventh position. The sex pheromones are inactivated when metabolized to their corresponding acids by insect aldehyde dehydrogenase. During this investigation it was demonstrated that the C16 aldehyde is a good substrate for human aldehyde dehydrogenase (EC 1.2.1.3) isoenzymes E1 and E2 with Km and Kcat. values at pH 7.0 of 2 microM and 0.4 mumol of NADH/min per mg and of 0.6 microM and 0.24 mumol of NADH/min per mg respectively. A vinyl ketone analogue of the pheromone inhibited insect pheromone metabolism; it also inactivated human aldehyde dehydrogenase. Total inactivation of both isoenzymes was achieved at stoichiometric (equal or less than the subunit number) concentrations of vinyl ketone, incorporating 2.1-2.6 molecules/molecule of enzyme. Substrate protection was observed in the presence of the parent aldehyde and 5'-AMP. Peptide maps of tryptic digests of the E2 isoenzyme modified with 3H-labelled vinyl ketone showed that incorporation occurred into a single peptide peak. The labelled peptide of E2 isoenzyme was further purified on h.p.l.c. and sequenced. The label was incorporated into cysteine-302 in the primary structure of E2 isoenzyme, thus indicating that cysteine-302 is located in the aldehyde substrate area of the active site of aldehyde dehydrogenase. Affinity labelling of aldehyde dehydrogenase with vinyl ketones may prove to be of general utility in biochemical studies of these enzymes.     

Mitochondrial aldehyde dehydrogenase from higher plants

Aldehyde dehydrogenase has been purified to homogeneity from mitochondria of potato tubers and pea epicotyls. Although the enzyme had a high affinity for glycolaldehyde it also had a high affinity for a number of other aliphatic and arylaldehydes. It is proposed that the codification glycolaldehyde dehydrogenase (EC 1.2.1.22) should be abandoned in favour of mitochondrial aldehyde dehydrogenase (EC 1.2.1.3). The purified enzyme showed esterase activity and had properties similar to those reported for the mammalian mitochondrial aldehyde dehydrogenase. Although the natural substrate(s) for the enzyme is not known, the kinetic properties of the enzyme are consistent with it playing a role in the oxidation of acetaldehyde, glycolaldehyde and indoleacetaldehyde.